Sensing mechanism for record processing machine



June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 1957 17 Sheets-Sheet 1 30a MHOLJWI .ava Jar soa YUI (I NHUY Wild INVENTORS WILLIAM F HUGH 8Y6 H/Mfd/A/ LfOA/IID u- ATTORNEYS June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 1957 17 Sheets-Sheet. 2

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SENSING MECHANISM FOR RECORD PROCESSING MACHINE 17 Sheets-Sheet 3 Original Filed Jan. 4. 1957 NVENTORS WILLIAM F. HUCK 63H BY AMA/N LEONA M W I ATTORNEYS mww NM NR Q Q: R 0 M m g WEI June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 1957 1'? Sheets-Sheet 4 m D\ KM T m ,N m mF m V N T mMu M mwm u mmwwhnhHHHHHHHhHU wIvI L\ un m8 l m m i v 7 I. g 4 Q3 Q4 3 3 3 Q H 3 mm M @Q r l k Q] U QR 2% N8 Rm I r U Q I m m N \QN I g r #NN. SN L @131 FL 1% Tm m June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195? 17 Sheets-Sheet 5 INVENTORS I t WILLIAM E HUCK r g ;HAM1 LEONARD rl Q m ATTORNEY June 14, 1966 w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE 1'? Sheets-Sheet 6 Original Filed Jan. 4, 195'? I n I W 5 5 M R A Y M E T E v N WEL m WM N w A WA mm H am% W2 Julie 14, 1966, w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE 1'7 Sheets-Sheet '7 Original Filed Jan. 4, 195'? mom TM Nw X ATTORNEYS June 14, 1966 w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195? 1'7 Sheets-Sheet 8 INVE TORS WILL/AM ls Hucx GHAML/N LEONARD BY ATTORNEYS bbbbbbb June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 1957 17 Sheets-Sheet 9 K0 2\ z\ Q m Q a a g Q "a INVENTORS WILL/AM HUCK BHAMLIN LEONARD 314.24,, 792M414 *Ad ATTORNEYS June 14, 1966 w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 195'? 1'? Sheets-Sheet 1O INVENTORS WILLIAM E Huck BYGZHIMLl/VZIO/VIZO 2. yz -x ATTORNEYS M oooooooooooooo 0000000000000000 0000000000000000 0000000000000000 OOOOOOOOOOOOOOOO June 14, 1966 w. F- HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195'? 17 Sheets-Sheet 11 INVENTORS W/LL/AM I. HUCK eHAMLlN LEONARD ATTORNEYS June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 1957 17 Sheets-Sheet 12 bill INVENTORS W L F- HUCK BGYT AMA/L //v A [0/1/4400 ML 972M445 ATTORNEYS June 14, 1966 w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 195'? 17 Sheets-Sheet 13 June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195'? 17 Sheet5$heet 14 ATTORNEYS June 14, 1966 w. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4, 1957 17 Sheets-Sheet 15 I E1- 4/5 j ////%4ao I lfi'vNToas WILLIAM E'HuoK G-HAMLIN LEONARD BY 614%; M,

ATTORNEYS June 14, 1966 W. F. HUCK ETAL SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195'? 1'7 Sheets-Sheet 16 Ti c135.

mvz TORS 6 WILLIAM Ham 447, Q-Hnmquv Leo/woo 447-" 44 448 614% M /ATTORNEYS June 14, 1966 w. F. HUCK ETAL 3,256,423

SENSING MECHANISM FOR RECORD PROCESSING MACHINE Original Filed Jan. 4. 195'? 17 Sheets-Sheet l7 INVENTORS WlLL/A/Yl E HUCK -HHMLIN LEONA o [ATTORNEYS United States Patent 3,256,423 SENSING MECHANISM FOR RECORD PROCESSING MACHINE William F. Huck, Forest Hills, N.Y., and George H.

Leonard, Darien, Conn., assignors, by mesne assignments, to William F. Huck, doing business as Huck Company, New York, NY.

Original application Jan. 4, 1957, Ser. No. 632,525, now Patent No. 3,070,366, dated Dec. 25, 1962. Divided and this application Nov. 29, 1962, Ser. No. 260,935

12 Claims. (Cl. 23561.11)

This invention relates to an improved business machine and more particularly to improvements in a machine for sensing information on punched cards; and this application is a division of our prior application, Serial No. 632,525, filed January 4, 1957, and entitled, Record Processing Machine, now Patent Number 3,070,366, issued December 25, 1962.

The machine of the invention is useful by itself for a variety of tasks such as punching record indicia in the form of perforations in record cards, sensing data on record cards and providing a statistical analysis thereof, and sorting record cards into categories based on the information sensed from or punched on the cards.

The machine is also useful for driving and/or directing the activities, e. g., the printing of bills, dick strips and the like, of one or more auxiliary machines in response to information sensed from record cards processed in the machine or abstracted directly from said cards in such auxiliary units. In addition, the machine of the invention, whether used with or independently of such units, is useful in combination with computers, memory devices and the like for such tasks as punching more detailed information on a card at one station in the machine in response to signals from a memory device acting on abbreviated information sensed at 'a previous station and relayed to the memory device.

Generally, the machine of the invention comprises a combination of assemblies, each of which contributes to the processing and feeding of record cards or the like at speeds of the order of 130 vto 390 per minute from a magazine, over sensing and punching stations, and through a card return unit to a stacking and sorting unit while recording statistical information in a counter assembly.

The machine and its major component parts have a considerable number of unique features and important advantages. One outstanding advantage is that the machine is readily adaptable to sensing and/or recording information on cards in the form of round holes or more closely spaced rectangular perforations in accordance with prevailing practices, and of being equally adaptable to other indicia-recordin'g systems as well. Another advantage is that the sensing and/or punching of information can, if desired, be restricted to a preselected area of the record cards.

Still another advantage and most unique feature is that the operating par-ts, particularly of the sensing and punching assemblies, are situated under rather than around or over the travel path of the cards, thus making the cards visible at all times, while said assemblies are themselves readily accessible and replaceable. Further, the sensing assemblies are provided with means for automatically interrupting their respective operations when a card is not presented, or is improperly presented, to them and, upon signal, for repeating their operations in identical manner even though, in the case of the sensor, no new cards are presented and, in the case of the punch, no new signals are received.

The sorting and stacking assemblies, like the sensing, punching, card return and counter assemblies, have the 3,256,423 Patented June 14, 1966 advantage, common to them, of being modular in the sense that their number and location can readily be altered to suit. Thus, for example, the sensing and punching assemblies are interchangeable, being mounted and operated in substantially the same manner; the card return is equally effective whether mounted directly on the basic machine or on an auxiliary device some distance away; the stacker assembly can collect the processed record cards in a single stack, in up to four preselected categories as indicated by signals received from the sensor or an external source if the basic unit alone is used, or in as many as about sixty categories if a sufficient number of auxiliary units are connected to the basic unit embodying this invention; and the counter assembly can readily be adapted to accommodate an almost indefinite number of counters.

Many of the assemblies, particularly the sensing, assembly operates on the principle of effectively translating the relatively weak impulse of an actuated signal device into a force, derived from the machine drive, of sufiicient strength to accomplish an intended function such as sending a signal from a sensor. Furthermore, and perhaps most important for speed of operation, these translations of relatively weak impulses into relatively strong actuating forces advantageously take place while the impulses for the next cycle are already being prepared.

These and innumerable other advantages, as well as the utility of the machine embodying the invention and subcombinations thereof will become apparent from the following description of a specific embodiment selected for illustrative purposes only, said description being made with reference to the accompanying drawings, wherein:

FIGURES 1 to 10, inclusive, illustrate the general arrangement and drive mechanism of the basic unit. FIGURE 1 is a perspective view of the assembled unit; FIGURE 2 is a View of a typical card; FIGURE 3 is a front view of the assembled unit with the casing broken away; FIGURE 4 is a plan view of the table taken on section line 4-4 of FIGURE 3; FIGURE 5 is a front view of the machine with the housing removed to show the drive mechanism, the counter assembly being omitted; and FIGURES 6 to 10, inclusive, are sectional views are sectional views taken on the correspondingly mum bered section lines of FIGURE 11; and FIGURE 14 is a horizontal section taken on section line 1 414 of FIGURE 13.

FIGURES 15 to 30, inclusive the sensing assembly 400, shown schematically in FIGURES 1 and 3. FIG- -URE 15 is a plan view taken on section line 15-15 of FIGURE 3; FIGURES 16 and 17 are opposite end views taken on the correspondingly numbered section lines of FIGURE 15; FIGURE 18 is a longitudinal section taken on section lines 1818 of FIGURE 16; FIGURES 19 and 20 are views taken in opposite directions on the correspondingly numbered section lines of FIGURE 16; FIGURE 21 is a plan view taken on section line 2121 of FIGURE 18; FIGURE 22 is a view taken on section line 22-22 of FIGURE 15; FIGURE 23 is a view taken on section line 2323 of FIGURE 20; FIGURE 24 is a view similar to FIGURE 23 showing another position of the parts; FIGURE 25 is a view, on an enlarged scale, taken on section line 2525 of FIGURE 15 FIGURE 26 is a view similar to FIGURE 25 showing the par-ts in a diiierent position; FIGURES 27 and 28 are plan views 3 taken on the correspondingly numbered section lines in FIGURES 25 and 26, respectively; FIGURE 29 is a detail in perspective illustrating the support and operating means for the guide channels; and FIGURE 30 is a perspective view of the elements illustrated in FIGURES 23 and 24.

General assembly The basic unit 100 of the machine of the invention comprises mechanism for advancing record cards such as illustrated in FIGURE 2 individually and in rapid succession from a magazine 200 along the top of the unit 100 to one or more sensing stations 400 and punching stations 600, as illustrated in FIGURES 1 and 3. The basic unit may be, preferably is, provided with a stacker 800 for selectively collecting record cards that have passed through the sensing and punching stations into two or more classified stacks, a card return 700 that may be attached directly to the basic unit 100, as shown, or to the last one or more auxiliary units operated by and in conjunction with the basic unit, and a counter 900.

The structural framework of the basic unit 100 includes, as best shown in FIGURES 4 to 10, a lower U-frame comprising from and rear frame members 101 and 102 and a transverse frame member 103, vertical bulkheads 104, 105 and 106, front and rear longitudinal braces 107 and 108 and upper longitudinal members 109 and 110. For mobility, the basic unit is provided with casters 111 and, for levelling, with suitable levelling devices 112.

Drive mechanism of basic unit The drive for powering the card return, stacker, counter and any auxiliary units between the basic unit and the card return is from a motor 120 to a main drive shaft 121 by way of a belt-connected variable pitch pulley 122 and companion sheave 123, and a gear train 124, 125, 126, 127, 128 for rotating the main drive shaft 121 at a speed of one revolution per machine cycle. To adjust this speed by means of the belt-connected variable speed pulleys 122 and sheave 123, the motor 120 is mounted on a rack 129 pivoted on a pin 130 between bulkheads 104 and 105 and adjusted to a preselected position by means of translating screw and hand wheel 131 against the action of a spring 132. Conveniently, a pointer 133 is mounted on a rack 129 at the pivot pin 130 to indicate speed on an indicator 134 calibrated in terms of cards per minute.

The main drive shaft 121 runs along substantially the entire length of the unit from bulkheads 104 to 106. At the extreme left end, the shaft is provided with a timing device 135 and at the extreme right end, as best shown in FIGURES 4 and 5, with a coupling member 136 for transmitting the drive to the card return mechanism 700 and, if desired, to one or more auxiliary units that may .be interposed between the basic unit 100 and the card return unit 700. Between bulkheads 105 and 106, the main drive shaft 121 carries a geared pulley 137 and timing belt 138 for driving, likewise at precisely one revolution per machine cycle, a card stacker cam shaft 801 by way of geared pulley 80-2 and a tensioning idler 803, as shown best in FIGURE 10. In addition, the main drive shaft 121 carries eccentrics 129 secured thereto by collars 130 for operation of the counter mechanism 900.

To prevent reverse movement of any portion of the machine with consequent damage, maladjustment or jamming of the record cards, the shaft 141 for sheave 123 and gear 124 is provided with an anti-reverse clutch 142. A hand wheel 143 is fixed to the shaft 141 to enable the operator easily to adjust, test and clean the machine.

The idler gear 127 in the train of gears 124-128 engages a gear 144 on a work shaft 145 carrying a fly wheel 146 for steadying the drive of the machine, a miter gear 147 for driving the card feed mechanism by way of companion miter gear 148, a cam 149 for operating a card interrupt device, which is optional on the basic unit, and a cam 150 for actuating a work operator for the sensing and punching mechanism 400 and 600, respectively. The

miter gear 148 is journalled for rotation between a fixed The work operator is an assembly designed to provide the forces necessary to a proper operation of sensing units, punch units and possibly other units on the work table of the basic unit. Basically this is accomplished by imparting vertical reciprocation to substantially the entire sensing unit and punching unit, for example, in such a manner as to relieve sensing elements and Bowden wires, individually or in groups, from exerting the entire force necessary to perform their respective functions in a given sensing or punching operation, as will become more evident in the detailed descriptions of the sensing and punching units that are to follow.

Underneath the longitudinal frame members 109 and between the longitudinal frame members 110, and to the right of the record card magazine 200 and rails 201, 202, as seen in FIGURE 4, a rectangular frame 300 is provided for vertical reciprocation guided by four bearing blocks 301. As seen in FIGURE 11, the work operator frame 300 is divided into any desired number of sections by means of cross members 302 to accommodate sensing and punching assemblies described later.

H-shaped spring plates 303 are suitably made fast, one to each of the ends of the work operator frame 300, for carrying the upper ends of a plurality of tension springs 304. The lower ends are secured to U-shaped spring plates 305 carried by generally Y-shaped braces 306 that are secured'to longitudinal frame members 109 and 110.

The work operator frame 300 is supported against the downward pulling action of the tension springs 304 by links 307 pivotally connected to the ends of the frame and also to arms 308 and 309 adjacent the left end of the work operator frame 300. The ends of the arms 308 and 309 are linked together by another link 310, as shown best in FIGURE 12. The arms are keyed to the ends of oscillatable shafts 311 and 312 which are parallel to and below the sides of the work. operator frame 300. The other ends of the shafts 311 and 312 are made fast to arms 313 and 314 each carrying, like arms 308 and 309, links 307 having one end pivoted on the right end of the work operator frame 300.

The arm 308 fast on the shaft 311 is provided with a cam follower 315 for following the contour of the work operator cam 150 on the work shaft 145.

It is apparent, therefore, that as the work operator earn 150 rotates, the cam follower 315 will be urged to follow its contour by action of springs 304 so as to oscillate the arms 308 and 309, and therefore also shafts 311 and 312 which in turn oscillate the arms 313 and 314 so that the four links 307 act simultaneously and with equal force to raise and lower the work operator frame 300 once for each revolution of the work shaft 145.

Sensor One or more sensor assemblies may, if desired, be supported on the frame for actuation by a work operator 300. In the basic unit illustrated by way of example in FIGURES 15 to 30 of the drawing, a sensor 400 is shown in the first work station immediately to the right of the rail members 201 and 202 of the card feed mech anism.

It is the function of the sensor to sense whatever perforations there are in a record card advanced to the sensing station and to transmit the sensed information to other parts of the basic unit, e.g., the punch, the counter or the stacking mechanism or any combination thereof and, if auxiliary units are operated in conjunction with the basic unit, to said auxiliary units as well. The sensing mechanism is also capable of receiving a repeat signal that will cause the sensor to lock in a sensed signal pattern and to repeat the same signal for a number of cycles depending upon the information sensed and to transmit such signals to one or more auxiliary units and,

if desired, to the counter. Signal-receptive means are also provided for releasing a locked-in signal pattern.

A unique feature of the sensing mechanism described is that it can readily be adapted, as will appear, to the sensing of either circular or the more closely spaced rectangular perforations that are predominantly used in record cards today, as well as to other perforated record indicia. It is also unique in that it does not require a massive supporting structure to surround the card being sensed and therefore has the advantage of easy correction in the event of a jam. The sensing mechanism is entirely below the work table of the basic unit, only a cover plate, which is readily removable, being above the path of the cards.

As shown best in FIGURES 15 to 30, the sensor comprises a rectangular frame that includes a left face plate 401 (left as viewed from the front of the basic unit 100 and as in FIGURE 16), a right face plate 402, a front end block 403 and a rear end block 404, these frame members being fastened together rigidly by means of machine screws and locating pins, not shown.

Up to twelve intermediate plates 405 are secured between and parallel to plates 401 and 402 by means of aligning rods 406 and chamfered aligning buttons 407, the intermediate plate 405 adjacent the right face plate 402 being spaced from the interior face thereof by a ledge 408 on the plate 402.

The entire frame, including plates 401, 402 and 405, and blocks 403 and 404, is supported on cross braces 409 between longitudinal frame members 109 and 110, at the left side, by means of rails 201 and 202 and machine screws 410 threaded into left face plate 401 and at the right side by means of a bevelled plate 411 and machine screws 410 threaded into right face plate 402.

The upper ends 412 of the intermediate plates 405 form a sensing table that is preferably covered by a cover 413 on which a card rests while in sensing position. The cover has holes large enough to permit penetration by sensor fingers 414 but small enough to prevent chad accidentally entrained with the cards from entering the sensor, as shown in FIGURE 15, and secured, under rails 201 and 202, to the left cross brace 409.

To help maintain a record card that has been advanced to the sensing position by the assemblies 214-218 reciprocating longitudinally in the grooves 223 of the rails 224 and properly positioned over the sensing station by a pair of spring-biased stops 213 against the upward thrust of sensor fingers 414, a cover 415 is releasably locked over and across the path of the cards by suitable snap locks 416. As shown best in FIGURES 18 and 2 1, the locks 416 comprise plates 417 slidable in longitudinal blocks 418 for engaging lips 419 of the cover 415 under the action of springs 420. The cover 415 can, therefore, readily be removed if desired simply by pulling knobs 421 and lifting.

To enable the sensor fingers 414 to move through a card perforation, as shown in phantom in FIGURE '26, the underside of the cover 415 is provided with longitudinal grooves 422. The ribs 423 formed between the grooves 422 are suitably bevelled as shown at 424 to assist in properly guiding the record cards and spaced to avoid sensor fingers penetrating through either round holes or the more closely spaced rectangular perforations of cards being processed. The tops of the intermediate plates 405 are preferably also bevelled, as shown at 425, particularly if operation without the cover 413 is contemplated.

As shown best in FIGURES 16 to 18, the underside of the cover 415 is preferably also provided with narrow transverse grooves 426 to accommodate a card detecting mechanism, and a wider transverse groove 427 for avoiding contact, and possible smearing, of printed matter on the faces of the cards. To assist in reading the printed matter, which is often applied. to the cards in reverse, the cover is preferably made of a transparent material and provided with a mirror 428.

changing their positions relative to one another.

With the exception of the sensor fingers 414, the parts of the sensor mechanism thus far described remain stationary during operation.

The sensor fingers 414 are, as shown best in FIGURES 25 and 26, the upper extremities of sensor slides 430, which are slidable vertically in the slots 431, as shown in FIGURE 15, of the intermediate plates 405. Inasmuch as the construction and operation of all the sensor slides are alike, the description thereof with reference to one sensor slide 430 will suffice.

In the reset position illustrated in FIGURE 25 the sensor slide 430, confined for vertical movement in the slot 431 by adjacent sensor guide channels 432 parallel to and between the plates 430, is pushed upward by upward movement of a flipper 433 in the same slot 431, the cammed head 434 thereof being in engagement with the cammed foot 435 of the slide 430.

The flipper 433 has a notch 436 engaged by the toe 437 of a flipper channel 438 mounted at its ends 439, as shown best in FIGURE 18, on front and rear operating channels 440 for vertical reciprocation between adjacent intermediate plates 405. The operating channels 440, together with a front face plate 441 and. a rear face plate 442, are secured by means of mounting blocks 443 to the work operator frame 300. It will be apparent, therefore, that as the work operator frame 300 moves up and down onceduring each revolution of the work shaft and as determined by the contour of the work operator cam 150, the operating channels 440 and face plates 441, 442, and therefore the flippers 433, will likewise be raised and lowered.

In order to urge the sensor slide 430 to rise and thereby the finger 414 to sense a record card in the sensing position when the flipper 433 rises, the flipper is biased for counterclockwise rotation about the toe 437 of the flipper channel, as seen in FIGURE 25, by means of a spring 445, the upper and lower ends of which are anchored in the upper bend of the next adjacent flipper channel 430 and in the body of the flipper 433, respectively. This, as well as the movement applied to the flipper by upward movement of the toe 437, urges the cammed head 434 against the foot 435 and so transmits the upward movement of the work operator frame 300 to the sensing finger 414.

If there is a perforation in the card at the position being sensed by the finger 414, as illustrated in FIGURE 25, the finger encounters no obstruction to movement into a groove 422 of the cover 415, thus permitting the sensor slide 430 and flipper 433 to move upward without The flipper 433 is lowered on the downstroke of the flipper channel 438 in the position shown in FIGURE 25 to thereby engage and press down with its foot 446, as illustrated in FIGURE 27, staggered Bowden cables 447 protruding upward from a Bowden terminal plate 448 made fast to the underside of the sensor frame by means of machine screws 449 threaded into the left and right face plates 401, 402. The signalling of a perforation is, therefore, accomplished by pushing the corresponding Bowden ends while the sensed card is moved to its next station.

Before proceeding further with the description, it is noted that the sensing and signalling mechanism described is as readily adaptable to record cards having more closely spaced rectangular perforations as it is to those having round holes, the only departures from the mechanism specifically described herein for illustrative purposes being that the intermediate plates 405 would be provided with a correspondingly greater number of more closely spaced slots 431 to accommodate the greater number of sensor slide and flipper assemblies 430, 433 required, and the feet 446 of the flippers would be made smaller so as directly to actuate one rather than two Bowden cables in view of the limitation on the spacing thereof.

It is to be understood also that in many instances there is no necessity for sensing more than a limited area of the 

1. IN A MACHINE OF THE CLASS DESCRIBED, SENSING MEANS COMPRISING VERTICALLY MOVABLE SENSOR FINGERS, EACH FINER BEING ON THE UPPER END OF A SENSOR SLIDE, AN ASSOCIATED FLIPPER FOR EACH SENSOR SLIDE PIVOTALLY SUPPORTED IN SIGNALLING POSITION BY A VERTICALLY RECIPROCABLE FLIPPER CHANNEL, EACH SENSOR SLIDE AND CORRESPONDING FLIPPER HAVING ENGAGING CAM FACES ADJACENT THEIR ENDS, SAID FLIPPER BEING BIASED TO ENGAGE ITS CAM WITH THE CAM ON ITS SENSOR SLIDE TO ELEVATE THE SENSOR SLIDE THEREWITH AS A UNIT UPON UPWARD MOVEMENT OF ITS SUPPORTING FLIPPER CHANNEL WITHOUT CHANGE FROM THE SINGALLING POSITION WHEN THERE IS NO OBSTRUCTION TO MOVEMENT OF THE SENSOR FINGER INTO A CARD PATH, AND SAID CAMS PIVOTING THE FLIPPER TO A NON-SIGNALLING POSITION UPON CONTINUED ELEVATION THEREOF RELATIVE TO THE SENSOR SLIDE WHEN THE LATTER IS ARRESTED BY ENGAGEMENT OF ITS SENSOR FINGER WITH A CARD, A SIGNAL RECEIVING ELEMENT UNDER THE FLIPPER IN ITS SIGNALLING POSITION FOR ENGAGEMENT THEREBY ON THE DOWNSTROKE OF THE FLIPPER CHANNEL, SAID SIGNAL RECEIVING MEANS BEING AVOIDED WHEN THE FLIPPER IS PIVOTED TO THE NON-SIGNALLING POSITION, AND RESET BARS FOR ENGAGING THE SENSOR SLIDES TO HOLD THEM AT THE END OF A DOWN STROKE OF THE FLIPPER CHANNEL FOR RESETTING ACTUATED FLIPPERS BACK TO SIGNALLING POSITION IN CAMMED ENGAGEMENT WITH ASSOCIATED SENSOR SLIDES. 